Parametrized polyconvex hyperelasticity with physics-augmented neural networks

Data-Centric Engineering Pub Date : 2023-01-01 DOI:10.1017/dce.2023.21

Dominik K. Klein, Fabian J. Roth, Iman Valizadeh, Oliver Weeger

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Abstract

Abstract In the present work, neural networks are applied to formulate parametrized hyperelastic constitutive models. The models fulfill all common mechanical conditions of hyperelasticity by construction. In particular, partially input convex neural network (pICNN) architectures are applied based on feed-forward neural networks. Receiving two different sets of input arguments, pICNNs are convex in one of them, while for the other, they represent arbitrary relationships which are not necessarily convex. In this way, the model can fulfill convexity conditions stemming from mechanical considerations without being too restrictive on the functional relationship in additional parameters, which may not necessarily be convex. Two different models are introduced, where one can represent arbitrary functional relationships in the additional parameters, while the other is monotonic in the additional parameters. As a first proof of concept, the model is calibrated to data generated with two differently parametrized analytical potentials, whereby three different pICNN architectures are investigated. In all cases, the proposed model shows excellent performance.

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物理增强神经网络的参数化多凸超弹性

摘要本文将神经网络应用于参数化超弹性本构模型的建立。这些模型在构造上满足了超弹性力学的所有常见条件。特别是在前馈神经网络的基础上，应用了部分输入凸神经网络(pICNN)结构。接收两组不同的输入参数，picnn在其中一组中是凸的，而对于另一组，它们表示不一定是凸的任意关系。这样，模型可以满足出于力学考虑而产生的凸性条件，而不必过于限制附加参数中的函数关系，这些参数不一定是凸的。介绍了两种不同的模型，其中一种模型可以表示附加参数中的任意函数关系，而另一种模型在附加参数中是单调的。作为概念的第一个证明，该模型被校准为由两个不同的参数化分析势生成的数据，从而研究了三种不同的pICNN架构。在所有情况下，所提出的模型都显示出良好的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Data-Centric Engineering

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